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Persistent colonization of Candida auris among inpatients rescreened as part of a weekly surveillance program

Published online by Cambridge University Press:  13 December 2023

Sebastian P. Arenas*
Affiliation:
University of Miami Health System, Miami, Florida
Patrice J. Persad
Affiliation:
University of Miami Health System, Miami, Florida
Samira Patel
Affiliation:
University of Miami Health System, Miami, Florida
Dipen J. Parekh
Affiliation:
University of Miami Health System, Miami, Florida Department of Urology, University of Miami Miller School of Medicine, Miami, Florida
Tanira B.D. Ferreira
Affiliation:
University of Miami Health System, Miami, Florida Division of Pulmonary, Critical Care, and Sleep Medicine, Department of Medicine, University of Miami Miller School of Medicine, Miami, Florida
Mirian Farinas
Affiliation:
University of Miami Health System, Miami, Florida
D. Joseph Sexton
Affiliation:
Mycotic Diseases Branch, Centers for Disease Control and Prevention, Atlanta, Georgia
Meghan Lyman
Affiliation:
Mycotic Diseases Branch, Centers for Disease Control and Prevention, Atlanta, Georgia
Hayley B. Gershengorn
Affiliation:
University of Miami Health System, Miami, Florida Division of Pulmonary, Critical Care, and Sleep Medicine, Department of Medicine, University of Miami Miller School of Medicine, Miami, Florida Division of Critical Care, Department of Medicine, Albert Einstein College of Medicine, Bronx, New York
Bhavarth S. Shukla
Affiliation:
University of Miami Health System, Miami, Florida Division of Infectious Diseases, Department of Internal Medicine, University of Miami Miller School of Medicine, Miami, Florida
*
Corresponding author: Sebastian P. Arenas; Email: s.arenas@med.miami.edu
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Abstract

We established a surveillance program to evaluate persistence of C. auris colonization among hospitalized patients. Overall, 17 patients (34%) had ≥1 negative result followed by a positive test, and 7 (41%) of these patients had ≥2 consecutive negative tests.

Type
Concise Communication
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Society for Healthcare Epidemiology of America

Candida auris is an emerging and often multidrug-resistant fungal pathogen that persistently colonizes patients and spreads in healthcare settings. 1Reference Meyer, Martin and Madad4 Studies have described duration of C. auris colonization in postacute care facilities (PACFs) and outside healthcare settings. Reference Bergeron, Bloch and Murray5,Reference Pacilli, Kerins and Clegg6 However, few data are available regarding its persistence among hospitalized patients, in whom colonization can increase the risk for developing C. auris candidemia. For instance, in one study, among 157 C. auris colonized patients in an intensive care unit, 27 (17%) patients developed C. auris candidemia and 7 of these patients developed a recurrent episode. Reference Briano, Magnasco and Sepulcri7 To expand our understanding of persistence of colonization, we share the findings of an ongoing C. auris surveillance program implemented to meet screening requests from PACFs before patient transfer and to evaluate changes in screening results among colonized patients while hospitalized.

Methods

Our surveillance program involved patients hospitalized in a 560-bed tertiary-care medical center in Miami, Florida who were known to be colonized with C. auris or were newly identified from admission screenings, point prevalence surveys (PPSs), or clinical cultures from a sterile and/or nonsterile body site. Admission screening criteria were met if a patient had a tracheostomy and/or arrived from a ventilator-capable PACF. Reference Pacilli, Kerins and Clegg6 All colonized patients were placed in a cohort in single-occupancy rooms of a 30-bed unit where daily cleaning was performed according to the institution’s protocol for patients on contact precautions for multidrug-resistant organisms (MDROs). Specifically, a hydrogen-peroxide–based disinfectant from the Environmental Protection Agency (EPA) List P was used daily as well as terminal cleaning with UV-C disinfection. This retrospective cohort study included all cases with at least 1 positive C. auris screening or clinical test and who were admitted to the C. auris–designated ward during the surveillance period. None of the patients were involved in a C. auris decolonization protocol, but patients with central lines did receive chlorhexidine gluconate (CHG) bathing according to policy. Each patient was counted only once. The surveillance screening program began on December 13, 2021, and remains active to date; however, the end of the data analysis period was set at July 26, 2022. Follow-up patient screening was conducted initially twice weekly until discharge and later transitioned to weekly due to swab shortages. Screening was performed using rt-PCR from axilla and groin composite swabs Reference Bergeron, Bloch and Murray5Reference Arenas, Patel and Seely8 via an on-site, laboratory-validated, BioGx C. auris BD Max instrument (REF 350-070-C-MAX), and samples were collected by trained nurses assigned to the ward. We retrospectively evaluated baseline characteristics and clinical and outcomes data from the electronic medical record (EMR). The University of Miami Institutional Review Board approved this analysis (no. 20210224).

Results

In total, 50 colonized patients from the surveillance program during the analysis period were reviewed. The median age was 68 years (interquartile range, 61–78), and 31 patients (62%) were identified as colonized on admission (Table 1). The remaining 19 patients were identified during their hospitalization. Also, 37 patients (74%) were admitted directly from PACFs, of whom 33 (89%) came from facilities with known ongoing transmission of C. auris. Of the 50 patients, 28 (56%) had a prior hospitalization within 1 year of their index admission. The median number of occasions that patients were tested was 10.5 (IQR, 4–23), with a median of 9 positive results (IQR, 4–19) and 950 days as the maximum length of time from first positive to last positive result. Furthermore, 18 patients (36%) were still admitted at the end of the analysis period, and 10 patients (20%) died; however, none of the patients who died had C. auris invasive infections documented at the time of death.

Table 1. Characteristics of Cohort

Note. IQR, interquartile range.

a Data are no. (%) unless otherwise specified.

b Manually abstracted from electronic medical record.

c Based on admission screening program data capturing different transfer locations and designation of high-risk facilities.

In total, 17 (34%) of the colonized patients had at least 1 negative result followed by a positive result, and of those, 7 (41%) had ≥2 consecutive negative results. For instance, case patient number 26 had 7 consecutive negative results followed by 1 positive result (Fig. 1). Of the 7 patients with ≥ 2 consecutive negative results, 2 patients (29%) remained negative up to discharge or the end of the data analysis period: case patient number 40, with 7 consecutive negative results, and case patient number 49, with 34 consecutive negative results (Fig. 1).

Figure 1. Persistence of C. auris colonization in a hospitalized cohort of patients. This figure shows the number of negative and positive screening tests per week; each block represents a week in each patient’s separate timeline (weeks 1–33 on the top row). Gray blocks with a “1” inside represent a positive screening result and black blocks with a “0” inside represent a negative screening result. Blocks that are half gray and half black with a “2” inside represent a total of 2 tests for that week (1 positive test and 1 negative test result in the same week). Also, 2 zeros inside a black block “00” represent 2 negative results in the same week, and a number “2” inside a gray block represents 2 positive tests in the same week. Blocks with asterisks inside represent a C. auris bloodstream infection (see legend) and an empty gray block(s) represents a gap in testing due to the patient leaving the cohort unit where surveillance took place. The total number of tests and positive tests is also shown as well as disposition and positivity rates.

During their admission, 5 patients (10%) developed C. auris candidemia. Among them, 3 were identified as colonized prior to developing C. auris candidemia (median days to C. auris candidemia from colonization, 51; IQR, 31–81). The fourth and fifth patients did not have prior documented C. auris history and did not meet criteria for C. auris screening on hospital admission. The fourth patient (no. 33) was identified due to C. auris candidemia on admission to the hospital and the fifth patient (no. 34) developed C. auris candidemia during hospitalization. Of these 5 patients, 3 had peripherally inserted central catheters, and 2 of these 3 were on mechanical ventilation at the time of identification. Also, 2 of these patients were discharged home, 1 was transferred to a PACF, and 1 died in the hospital 125 days after C. auris candidemia clearance. The last remaining patient continued to be admitted after the analysis period ended and had the longest length of stay (LOS) of the cohort (958 days).

Discussion

Our data demonstrate the persistence of C. auris colonization and support findings of prolonged colonization among hospitalized patients, even after occasional negative results, as reported in prior studies in different settings. Reference Pacilli, Kerins and Clegg6,Reference Briano, Magnasco and Sepulcri7 In our experience, PACFs routinely request C. auris screenings prior to transfer and rely on these results to accept or decline new patients. This situation highlights concerns about using negative results as criteria to transfer patients or remove contact precautions because 1 or multiple negative results may not ensure that a patient is no longer colonized. 9

Furthermore, some PACFs appear to be reservoirs for C. auris based on our admission screening. Resource limitations have been noted in prior studies among nursing home infection prevention and control (IPC) staff; for example, in one survey, 61% of respondents had no IPC training and 54% had at least 2 other responsibilities in addition to IPC. Reference Herzig, Stone and Castle10 In view of these findings, education on the use of enhanced-barrier precautions, placement in cohorts, and PPSs may be needed to prevent transmission of C. auris or other MDROs. PPSs should be used to detect unknown C. auris cases and not to continuously reassess known cases. 9 However, if rescreening of a colonized patient is being considered in an acute or postacute care setting, it should be done in consultation with public health agencies.

To our knowledge, this is the first report describing longitudinal trends of C. auris colonization among hospitalized patients. The limitations of this analysis include limited generalizability based on our single-center study design. Unlike other studies, Reference Bergeron, Bloch and Murray5 we did not perform fungal cultures on the screening specimens; thus, we were unable to address organism viability. Additionally, because patients were only tested while hospitalized, we were not able to determine the persistence of colonization outside the ACH setting. Finally, we were unable to control the time of sample collection; therefore, we were unable to determine whether it occurred before or after CHG bathing.

Our findings suggest that screening of patients for discharge, transfer, or to assess C. auris colonization clearance may not be warranted. As C. auris continues to spread, Reference Lyman, Forsberg and Sexton11 known strategies to prevent transmission require implementation and research on methods to decolonize or decrease C. auris skin burden.

Acknowledgments

We thank the members of the UHealth-DART Research Group for their support and feedback on this project. The findings and conclusions of this report are those of the authors and do not necessarily represent the official position of the Centers for Disease Control (CDC).

Financial support

This study used own funding from the University of Miami Health System.

Competing interests

None of the authors have any conflict of interests to report.

References

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Figure 0

Table 1. Characteristics of Cohort

Figure 1

Figure 1. Persistence of C. auris colonization in a hospitalized cohort of patients. This figure shows the number of negative and positive screening tests per week; each block represents a week in each patient’s separate timeline (weeks 1–33 on the top row). Gray blocks with a “1” inside represent a positive screening result and black blocks with a “0” inside represent a negative screening result. Blocks that are half gray and half black with a “2” inside represent a total of 2 tests for that week (1 positive test and 1 negative test result in the same week). Also, 2 zeros inside a black block “00” represent 2 negative results in the same week, and a number “2” inside a gray block represents 2 positive tests in the same week. Blocks with asterisks inside represent a C. auris bloodstream infection (see legend) and an empty gray block(s) represents a gap in testing due to the patient leaving the cohort unit where surveillance took place. The total number of tests and positive tests is also shown as well as disposition and positivity rates.